Charging infrastructure and technologies – MCQs – EE

1. The main function of an EV charging station is to:

(A) Store electrical energy

(B) Supply electrical energy to recharge EV batteries

(D) Provide mechanical power

2. The three main types of EV charging are:

(A) AC slow, AC fast, and DC fast charging

(B) Solar, wind, and thermal charging

(D) Plug-in, wireless, and hybrid charging

3. Level 1 charging typically uses:

(A) 120V AC single-phase supply

(B) 240V AC three-phase supply

(D) 48V DC supply

4. Level 2 charging commonly uses:

(A) 12V DC supply

(B) 240V AC single- or three-phase supply

(D) 1000V AC supply

5. Level 3 or DC fast charging operates typically at:

(A) 120V DC

(B) 240V AC

(D) 24V DC

6. The typical power range of DC fast chargers is:

(A) 1–2 kW

(B) 3–7 kW

(D) 10–20 W

7. The standard connector used for DC fast charging in Europe is:

(A) CHAdeMO

(B) CCS Combo 2

(D) GB/T

8. The CHAdeMO standard was developed in:

(A) USA

(B) Japan

(D) China

9. The CCS (Combined Charging System) supports:

(A) Only AC charging

(B) Only DC charging

(D) Wireless charging only

10. The Type 2 connector is commonly used in:

(A) North America

(B) Europe

(D) China

11. The Type 1 connector is primarily used in:

(A) Japan and North America

(B) Europe

(D) India

12. The main communication protocol used between EV and charger is:

(A) CAN bus

(B) PLC (Power Line Communication)

(D) Wi-Fi

13. The onboard charger in an EV converts:

(A) DC to AC

(B) AC from the grid to DC for the battery

(D) DC to mechanical power

14. Smart charging infrastructure allows:

(A) Controlled and optimized charging based on grid conditions

(B) Random charging of vehicles

(D) Unregulated energy flow

15. The term V2G stands for:

(A) Voltage to Grid

(B) Vehicle to Grid

(D) Vehicle to Garage

16. In V2G technology, the EV:

(A) Only draws energy from the grid

(B) Can supply stored energy back to the grid

(D) Operates independently of the grid

17. Wireless charging for EVs is based on:

(A) Capacitive coupling

(B) Inductive power transfer

(D) Direct conduction

18. The main disadvantage of wireless EV charging is:

(A) Lower efficiency compared to plug-in charging

(B) High maintenance

(D) Limited charging safety

19. The smart grid supports EV charging by:

(A) Disconnecting power

(B) Balancing load demand dynamically

(D) Disabling communication

20. The main benefit of fast charging stations is:

(A) Reduced grid load

(B) Shorter charging time for EVs

(D) Smaller battery life

21. The OCPP protocol in EV charging stands for:

(A) Open Charging Point Protocol

(B) Over Current Protection Protocol

(D) Online Communication Protocol Platform

22. A home EV charger is usually rated between:

(A) 1–2 kW

(B) 3–22 kW

(D) 200–400 kW

23. Public DC fast chargers are typically installed:

(A) In homes only

(B) On highways and public stations

(D) Near water reservoirs

24. The main challenge in EV charging infrastructure is:

(A) Grid capacity and standardization

(B) Motor design

(D) Vehicle aerodynamics

25. Battery swapping stations are used to:

(A) Replace discharged batteries with charged ones

(B) Repair damaged batteries

(D) Recycle old cells

26. The efficiency of conductive EV charging is typically:

(A) 50–60%

(B) 70–80%

(D) 100%

27. The efficiency of wireless EV charging is approximately:

(A) 40–50%

(B) 60–70%

(D) 100%

28. The charging infrastructure that integrates renewable sources like solar energy is called:

(A) Hybrid Charging Station

(B) Renewable-integrated EV Charging Station

(D) Passive Charging Network

29. Bidirectional chargers are essential for:

(A) V2G and V2H applications

(B) High-speed AC charging

(D) Motor control

30. The future of EV charging infrastructure focuses on:

(A) Smart grids, high-power DC charging, and wireless systems

(B) Manual charging only

(D) Elimination of communication systems